JP4080136B2 - Coordinate input / detection device and storage medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a coordinate input / detection device for optically detecting a position coordinate indicated by an indication member such as a pen or a pointing means for inputting or selecting information, and the coordinate input / detection device as a main component. The present invention relates to an electronic blackboard system and a storage medium.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been known an electronic blackboard device capable of reading handwritten information written on a writing surface such as a whiteboard or a writing sheet using a writing tool with a dedicated scanner and outputting it to a recording paper with a dedicated printer. ing. On the other hand, in recent years, a coordinate input / detection device is arranged on the writing surface of the electronic blackboard device so that information written by hand on the writing surface can be input to a computer such as a personal computer in real time. An electronic blackboard system is also provided.
[0003]
For example, a software board made by Microfield Graphics, Inc. (Microfield Graphics, Inc.) is configured by arranging a coordinate input / detection device on a whiteboard, such as characters and pictures written on the whiteboard. It is a device that enables visual data to be imported into a computer in real time. In an electronic blackboard system configured using this soft board, visual data captured by the soft board is input to a computer and displayed on a CRT (Cathode Ray Tube), or displayed on a large screen using a liquid crystal projector. It is possible to output to recording paper with a printer. It is also possible to project a computer screen to which a soft board is connected onto the soft board with a liquid crystal projector and operate the computer on the soft board.
[0004]
Also, a display device for displaying characters and images, a coordinate input / detection device having a coordinate input surface (touch panel surface) disposed on the front surface of the display device, and a display device based on input from the coordinate input / detection device There is provided an electronic blackboard system that includes a display device and a control device that controls the display of the electronic blackboard portion, and includes a display device and a coordinate input / detection device.
[0005]
For example, in Smart 2000 manufactured by SMART Technologies Inc., a projection surface of a panel in a state where characters, pictures, graphics, and graphics images are projected onto the panel using a liquid crystal projector connected to a computer. Using a coordinate input / detection device (writing surface) disposed on the front surface of the (display surface), a process of taking handwritten information into the computer is performed. Then, the handwritten information and the image information are synthesized in the computer and can be displayed again in real time via the liquid crystal projector.
[0006]
In such an electronic blackboard system, an image input using a coordinate input / detection device can be displayed as an overwritten image on an image displayed on a screen displayed by a display device. Have already been widely used in the field, and its use effect is highly evaluated. In addition, the electronic blackboard system is also used as an electronic conference system by incorporating a communication function such as voice and image into a remote communication line.
[0007]
In recent years, various types of coordinate input / detection devices used in an electronic blackboard system with different detection methods have been considered. However, if a method suitable for application to the above-described electronic blackboard system is studied, input is possible without having a physical surface such as a coordinate input surface (touch panel surface), such as an optical type. Coordinate input / detection devices are considered promising.
[0008]
As such an optical coordinate input / detection device, various methods have been proposed. As an example of an optical coordinate input / detection device, there is a coordinate input / detection device described in JP-A-11-110116. The coordinate input / detection apparatus described in Japanese Patent Application Laid-Open No. 11-110116 scans laser beam light emitted from light sources provided in two optical units using a polygon mirror, and the laser beam light is scanned. It has a coordinate input / detection area formed by reflecting with a retroreflecting member. When light in the coordinate input / detection area is blocked by inserting an instruction means such as a fingertip or a pen into the coordinate input / detection area, the light receiving elements respectively provided in the two optical units The number of pulses of a pulse motor that rotates the polygon mirror is detected based on the light intensity distribution in the light source, and the emission angle of the light blocked by the indicating means is determined for each optical unit according to the detected number of pulses. The position coordinates into which the pointing means is inserted are detected by a triangulation method based on the emission angle of.
[0009]
An optical coordinate input / detection device that does not have a physical surface such as a coordinate input surface (touch panel surface) as typified above is a case where it is used by being mounted on a display screen of a display device. In addition to being excellent in visibility, its enlargement is relatively easy.
[0010]
[Problems to be solved by the invention]
However, according to the coordinate input / detection device described in the above-mentioned Japanese Patent Application Laid-Open No. 11-110116, a retroreflective member for reflecting the laser beam light by installing an optical unit for emitting the laser beam light upward. Since a part of is provided below, foreign matters such as dust and dirt accumulate on the retroreflective member provided below. In this way, when foreign matter such as dust or dirt accumulates on the retroreflective member, there is a problem that the detection of the coordinate position becomes unsatisfactory.
[0011]
Such a problem can be solved to some extent by installing an optical unit that emits laser beam light below and not providing a retroreflective member below, but when the optical unit is installed below, Foreign matter such as dust or dirt may adhere to the lens of the optical unit. In such a case, the coordinate input / detection device determines that a foreign object such as dust or dust has been inserted by the pointing means, so that incorrect information is transmitted as electronic data, and position coordinate detection is not possible. This will cause problems with reliability.
[0012]
An object of the present invention is to provide a coordinate input / detection device, an electronic blackboard system, and a storage medium that can improve the reliability of position coordinate detection.
[0017]
[Means for Solving the Problems]
  According to the first aspect of the present invention, there is provided an optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, and the light received by the light receiving element through the opening. In a coordinate input / detection device for detecting a two-dimensional position coordinate of an indicating means such as an indicating member or a finger that indicates the inside of a coordinate input / detection region based on the intensity distribution of the optical unit, the opening of the optical unit is closed and opened A cover means that can be moved back and forth, and a wiping member that is provided on the cover means and that wipes the transparent protective member when the cover means closes and opens the opening;When the shape abnormality determining means for determining whether or not the shape of the intensity distribution of the light received by the light receiving element is abnormal, and when the shape of the light intensity distribution is determined to be abnormal by the shape abnormality determining means First cover driving means for closing and opening the opening by moving the cover means forward and backward.
[0018]
Therefore, for example, when two or more peak points (dips) in the shape of the light intensity distribution appear or are wide, foreign matter such as dust or dust is present on the transparent protective member, so Assuming that the shape of the intensity distribution is abnormal, by moving the cover means forward and backward to the position where the opening is closed and opened, foreign matters such as dust and dirt on the transparent protective member are wiped off as the cover means moves. The member can be wiped off.
[0019]
  ClaimThe invention described in 2 includes an optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, and the intensity of light received by the light receiving element through the opening In a coordinate input / detection device for detecting a two-dimensional position coordinate of a pointing means such as a pointing member or a finger that points within a coordinate input / detection region based on a distribution, the opening of the optical unit is set to a position for closing and opening. Removable cover means, and a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening,Shape change determining means for determining whether or not the temporal change in the shape of the intensity distribution of light received by the light receiving element is abnormal, and the temporal change in the shape of the light intensity distribution by the shape change determining means is abnormal And a second cover driving means for moving the cover means forward and backward to close and open the opening when it is determined that
[0020]
Therefore, for example, when peak points (dips) in the shape of the light intensity distribution appear at the same location for a predetermined time or more, the light intensity distribution is due to the presence of foreign matter such as dust or dust on the transparent protective member. It is assumed that the temporal change of the shape of the cover is abnormal, and by moving the cover means forward and backward to the position where the opening is closed and opened, foreign matter such as dust and dirt on the transparent protective member accompanies the movement of the cover means. The wiping member can be wiped off.
[0021]
  Claim3The described invention,A third cover driving means for driving the cover means to close the opening when the operation of the apparatus is finished is provided.
[0022]
Therefore, it is possible to reliably prevent foreign matters such as dust and dust from entering the optical unit and adhesion of foreign matters such as dust and dust onto the transparent protective member when the apparatus is not used.
[0023]
  Claim4The described invention,The apparatus includes fourth cover driving means for driving the cover means so as to open the opening when the apparatus is activated.
[0024]
Therefore, even if the opening is closed while the apparatus is not used, the opening is opened when the apparatus is activated, so that the two-dimensional position coordinates of the pointing means are reliably detected.
[0025]
  Claim5The described invention,A cover drive declaring means for declaring the drive of the cover means, and a fifth means for closing and opening the opening by advancing and retracting the cover means when the drive of the cover means is declared by the cover drive declaring means. Cover driving means.
[0026]
Accordingly, the foreign means such as dust and dirt on the transparent protective member is wiped off by the wiping member in accordance with the movement of the cover means by moving the cover means forward and backward to the position where the opening is closed and opened by the operator's intention. Is possible.
[0031]
  Claim6The storage medium according to the invention includes an optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, and a position at which the opening of the optical unit is closed and opened. Used in a coordinate input / detection device comprising: a flexible cover means; and a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening. Reading to a computer that causes the computer to detect the two-dimensional position coordinates of the pointing means such as a pointing member or a finger that points within the coordinate input / detection area based on the intensity distribution of the light received by the light receiving element through the opening A storage medium storing a possible program, wherein the program determines whether or not the shape of the intensity distribution of light received by the light receiving element is abnormal Causing the computer to execute a shape abnormality determining function and a first cover driving function for moving the cover means forward and backward to close and open the opening when it is determined that the shape of the light intensity distribution is abnormal .
[0032]
Therefore, for example, when two or more peak points (dips) in the shape of the light intensity distribution appear or are wide, foreign matter such as dust or dust is present on the transparent protective member, so Assuming that the shape of the intensity distribution is abnormal, by moving the cover means forward and backward to the position where the opening is closed and opened, foreign matters such as dust and dirt on the transparent protective member are wiped off as the cover means moves. The member can be wiped off.
[0033]
  Claim7The storage medium according to the invention includes an optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, and a position at which the opening of the optical unit is closed and opened. Used in a coordinate input / detection device comprising: a flexible cover means; and a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening. Reading to a computer that causes the computer to detect the two-dimensional position coordinates of the pointing means such as a pointing member or a finger that points within the coordinate input / detection area based on the intensity distribution of the light received by the light receiving element through the opening A storage medium storing a possible program, wherein the program is abnormal in temporal change in the shape of the intensity distribution of light received by the light receiving element. And a second cover driving function for closing and opening the opening by moving the cover means forward and backward when it is determined that the temporal change in the shape of the light intensity distribution is abnormal. Are executed by the computer.
[0034]
Therefore, for example, when peak points (dips) in the shape of the light intensity distribution appear at the same location for a predetermined time or more, the light intensity distribution is due to the presence of foreign matter such as dust or dust on the transparent protective member. It is assumed that the temporal change of the shape of the cover is abnormal, and by moving the cover means forward and backward to the position where the opening is closed and opened, foreign matter such as dust and dirt on the transparent protective member accompanies the movement of the cover means. The wiping member can be wiped off.
[0041]
DETAILED DESCRIPTION OF THE INVENTION
A first embodiment of the present invention will be described with reference to FIGS. Here, FIG. 1 is an external perspective view schematically showing the electronic blackboard system 1. As shown in FIG. 1, an electronic blackboard system 1 includes an electronic blackboard portion 4 including a plasma display panel (PDP) 2 and a coordinate input / detection device 3 that are display devices, an apparatus storage portion 9, It is mainly composed. The device storage unit 9 includes a computer 5 such as a personal computer as a control device, a scanner 6 for reading an image of a document, a printer 7 for outputting image data to a recording paper, and a video player 8 (see FIG. 2). It is stored. As the PDP 2, a large screen type that can be used as an electronic blackboard is used. The PDP 2 and the coordinate input / detection device 3 are integrated so as to be positioned on the display surface 2a side of the PDP 2, and the coordinate input / detection region 3a of the coordinate input / detection device 3 substantially coincides with the display surface 2a of the PDP 2. Thus, the electronic blackboard portion 4 is formed. In this way, the electronic blackboard unit 4 accommodates the PDP 2 and the coordinate input / detection device 3, and constitutes the display surface (display surface 2a of the PDP 2) and the writing surface (coordinate input / detection region 3a) of the electronic blackboard system 1. ing.
[0042]
The coordinate input / detection device 3 has a coordinate input / detection area 3a which is a coordinate input / detection surface formed by a light flux film projected in a fan shape, as will be described in detail later. Light receiving that is a CCD (Charge Coupled Device) by blocking the light flux in the coordinate input / detection area 3a by inserting pointing means P (see FIG. 10) that is a pointing member such as a fingertip or a pen into the detection area 3a A light shielding type coordinate input / detection device that detects the indicated position by a triangulation method based on the light receiving position in the element 39 (see FIG. 5) and enables input of characters and the like is applied. Such a light-shielding coordinate input / detection device 3 does not have a physical surface such as a coordinate input surface (touch panel surface), and does not require a special material / mechanism. When the detection device 3 is mounted on the display surface 2a of the PDP 2 and used, an electronic blackboard system that is excellent in visibility and inexpensive can be provided.
[0043]
Further, although not shown in the figure, the PDP 2 is provided with a video input terminal and a speaker to connect various information devices such as a video player 8, a laser disc player, a DVD player, a video camera, and an AV device. However, the PDP 2 can be used as a large screen monitor. The PDP 2 is also provided with adjusting means (not shown) for adjusting the display position, width, height, distortion, etc. of the PDP 2.
[0044]
Next, the electrical connection of each part built in the electronic blackboard system 1 will be described with reference to FIG. As shown in FIG. 2, in the electronic blackboard system 1, a PDP 2, a scanner 6, a printer 7, and a video player 8 are connected to a computer 5, and the entire system is controlled by the computer 5. The computer 5 is connected to a controller 10 provided in the coordinate input / detection device 3 that performs the calculation of the coordinate position in the coordinate input / detection area 3a instructed by the instruction means P. The coordinate input / detection device 3 is also connected to the computer 5 through the computer 5. Further, the electronic blackboard system 1 can be connected to the network 11 via the computer 5, and data created by another computer connected on the network 11 is displayed on the PDP 2 or data created by the electronic blackboard system 1. Can be transferred to other computers.
[0045]
Next, the computer 5 will be described. Here, FIG. 3 is a block diagram showing an electrical connection of each part built in the computer 5. As shown in FIG. 3, the computer 5 includes a CPU 12 (Central Processing Unit) that controls the entire system, a ROM (Read Only Memory) 13 that stores a startup program and the like, and a RAM (Random) that is used as a work area of the CPU 12. Access Memory) 14, a keyboard 15 for inputting characters, numerical values, various instructions, a mouse 16 for moving a cursor, selecting a range, and the like, a hard disk 17, and a PDP 2 connected to the PDP 2. An interface (for connecting a controller 10, a scanner 6, a printer 7, etc.), a graphics board 18 for controlling display of an image to the network 11, a network card (or a modem) 19 for connecting to the network 11, and the like. I / F) 20 and a bus 21 for connecting the above-described units.
[0046]
The hard disk 17 includes an operating system (OS) 22, a device driver 23 for operating the coordinate input / detection device 3 on the computer 5 via the controller 10, drawing software, word processor software, and spreadsheet. Various application programs 24 such as software and presentation software are stored.
[0047]
The computer 5 also has a storage medium 26 that stores various program codes (control programs) such as the OS 22, device driver 23, and various application programs 24, that is, a floppy disk, a hard disk, and an optical disk (CD-ROM, CD-R). , CD-R / W, DVD-ROM, DVD-RAM, etc.), magneto-optical disk (MO), floppy disk drive device that is a device for reading program codes stored in a memory card, CD-ROM drive device, A program reading device 25 such as an MO drive device is mounted.
[0048]
The various application programs 24 are executed by the CPU 12 under the control of the OS 22 that is activated when the computer 5 is powered on. For example, when the drawing software is activated by a predetermined operation of the keyboard 15 or the mouse 16, a predetermined image based on the drawing software is displayed on the PDP 2 via the graphics board 18. The device driver 23 is also activated together with the OS 22 so that data can be input from the coordinate input / detection device 3 via the controller 10. When the operator inserts the instruction means P in the coordinate input / detection area 3a of the coordinate input / detection device 3 and draws a character or a figure with the drawing software activated as described above, the coordinate information is the description of the instruction means P. Is input to the computer 5 as image data based on the above, for example, and displayed as an overwritten image superimposed on the image on the screen displayed on the PDP 2. More specifically, the CPU 12 of the computer 5 generates drawing information for drawing lines and characters based on the input image data, and the graphics board 18 in accordance with the coordinate position based on the input coordinate information. Are written in a video memory (not shown). Thereafter, the graphics board 18 transmits the drawing information written in the video memory to the PDP 2 as an image signal, so that the same character as the character drawn by the operator is displayed on the PDP 2. That is, since the computer 5 recognizes the coordinate input / detection device 3 as a pointing device such as the mouse 16, the computer 5 performs the same processing as when drawing characters using the mouse 16 on the drawing software. Will be.
[0049]
Next, the coordinate input / detection device 3 will be described in detail. Here, FIG. 4 is an explanatory diagram schematically showing the configuration of the coordinate input / detection device 3. As shown in FIG. 4, the coordinate input / detection device 3 includes a horizontally-long rectangular coordinate input / detection region 3a having a size corresponding to the size of the display surface 2a of the PDP 2. The coordinate input / detection area 3a is an area that enables input of characters, figures, and the like by handwriting. Optical units 27 (left optical unit 27L and right optical unit 27R) that perform light emission and light reception are provided at predetermined mounting angles in the vicinity of corners located at both lower ends of the coordinate input / detection region 3a. Yes. These optical units 27 form a plane or a substantially plane, for example L₁, L₂, L_Three, ..., L_n(R₁, R₂, R_Three, ..., R_nA fan-shaped light flux film composed of a bundle of light (probe light) is projected in parallel along the surface of the display surface 2a of the PDP 2 so as to reach the entire coordinate input / detection region 3a.
[0050]
Further, the coordinate input / detection device 3 is provided with a retroreflective member R along the left and right sides and the upper side of the coordinate input / detection region 3a. These retroreflective members R are formed, for example, by arranging a large number of conical corner cubes, and have a characteristic of reflecting incident light toward a predetermined position regardless of the incident angle. . For example, the probe light L projected from the left optical unit 27L_FourAre reflected by the retroreflective member R and follow the same optical path again._Four'Is received by the left optical unit 27L. That is, the coordinate input / detection region 3a is also formed by the retroreflective member R. As shown in FIG. 4, each retroreflective member R arranged along the left and right sides of the coordinate input / detection region 3a is perpendicular to each retroreflective member R arranged along the upper side. However, the end portions between the retroreflective members R are not connected. Further, between the retroreflective members R, black marks M (M1, M2) having a low light reflectance are provided. In addition, black marks M (M3, M4) having a low light reflectance are also provided in the vicinity of the optical unit 27 (the left optical unit 27L and the right optical unit 27R). Although details will be described later, these black marks M (M1, M2, M3, M4) define both ends of the light receiving area in the light receiving element 39 that receives light in the coordinate input / detection area 3a. As described above, the optical unit 27 (the left optical unit 27L and the right optical unit 27R) is installed below, and the retroreflective member R is not provided below. It is possible to prevent the accumulation of foreign substances such as.
[0051]
Next, the optical unit 27 will be described. Here, FIG. 5 is a longitudinal front view showing the internal structure of the optical unit 27, and FIG. 6 is a bottom view thereof. As shown in FIGS. 5 and 6, the optical unit 27 includes a housing 28, an opening 28a formed in the housing 28 and communicating with the outside, a first holding plate 29, a second holding plate 30, an LD (Laser). A circuit board 31 that drives and controls a light source 34 that is a diode (semiconductor laser), a circuit board 32 that drives and controls a light receiving element 39, a back plate 33, and the like are provided. The light source 34, the diffusion lens 35, the half mirror 36, the protective glass 37 that is a transparent protective member located in the opening 28 a, the reading lens 38, and the light receiving element 39 are attached to the housing 28.
[0052]
Laser light emitted from the light source 34 is diffused by the diffusing lens 35 in parallel to the display surface 2a of the PDP 2 and in a fan shape (in this case, 90-), and enters the half mirror 36. The laser light incident on the half mirror 36 is transmitted through the half mirror 36, and further recursively reflected by the retroreflective member R after passing through the protective glass 37, and then returns to the half mirror 36 through the same optical path again. become.
[0053]
The retroreflected light reflected by the retroreflective member R and returned to the half mirror 36 is reflected by the half mirror 36 toward the reading lens 38 and enters the light receiving element 39 via the reading lens 38. The retroreflected light incident on the reading lens 38 is linearized by the action of the reading lens 38, and then is probed by a light receiving element 39 provided at a distance f (f is a focal length) from the reading lens 38. Light is received at different positions for each. As a result, a light intensity distribution is formed on the light receiving element 39 in accordance with the presence or absence of retroreflected light. That is, when the retroreflected light is blocked by the instruction means P, a point with a low light intensity (a peak point described later) is generated at a position corresponding to the blocked retroreflected light on the light receiving element 39. The light receiving element 39 that has received the retroreflected light generates an electrical signal based on the light intensity distribution of the retroreflected light (probe light), and outputs the electrical signal to the controller 10 described above.
[0054]
The protective glass 37 is provided in order to prevent foreign matters such as dust and dust from entering the housing 28. Further, even if the protective glass 37 is reflected by the surface of the protective glass 37 when the laser light traveling toward the retroreflective member R is transmitted through the protective glass 37, the light receiving element 39 receives the reflected light. In order to reflect in a non-directional direction, the PDP 2 is provided with an inclination of 6 ° with respect to the direction perpendicular to the display surface 2a.
[0055]
In addition, as shown in FIG. 7, unit cover mechanisms 51 are provided in the optical units 27 (the left optical unit 27L and the right optical unit 27R), respectively. The unit cover mechanism 51 is provided with a flat cover 52 that functions as a cover means. The cover portion 52 is provided so as to reciprocate between the unit opening position A and the unit closing position B so as to freely advance and retract. As the mechanism, the cover 52 is supported by a guide shaft 53 provided in parallel with each other and a helical gear shaft 55 that is driven by a motor 54 and rotates. That is, the cover 52 is slidably attached to the guide shaft 53 and is screwed to the helical gear shaft 55. Therefore, when the helical gear shaft 55 is rotationally driven by the motor 54, the cover portion 52 moves between the unit opening position A and the unit closing position B along the axial direction of the guide shaft 53 and the helical gear shaft 55. Then, as shown in FIG. 7B, when the cover 52 moves to the unit closing position B, the protective glass 37 of the optical unit 27 is at least covered by the cover 52. When the cover 52 is moved, the first micro switch 56 is switched on when the cover 52 is located at the unit opening position A, and the second micro switch 57 is located when located at the unit closing position B. Switch on. By detecting the switch-on state of the first to second micro switches 56 to 57, it is recognized where the cover portion 52 is located.
[0056]
8A is a front view of the cover portion 52, and FIG. 8B is a side view of the cover portion 52. As shown in FIG. As shown in FIG. 8, a lower part of the cover part 52 (a part facing the protective glass 37 of the optical unit 27) is formed of, for example, a felt material or a brush, and the optical unit 27 is moved when the cover part 52 is moved. A wiping member 58 that slides and wipes the surface is provided. The wiping member 58 is for wiping off foreign matters such as dust and dirt on the protective glass 37 as the cover 52 reciprocates.
[0057]
Next, the electrical connection of each part of the coordinate input / detection device 3 will be described with reference to FIG. As shown in FIG. 9, the controller 10 controls the light emission of the light source 34 of the optical unit 27 (left optical unit 27L, right optical unit 27R) and the light receiving element of the optical unit 27 (left optical unit 27L, right optical unit 27R). The controller 10 is provided with a CPU 40 that centrally controls each unit. The CPU 40 includes a ROM 41 that stores programs and data, a RAM 42 that stores various data in a rewritable manner and functions as a work area, a timer T that measures time, an interface 43 for connection to the computer 5, a motor 54, a cover A wiping switch 59 that functions as drive declaring means and declares the removal of foreign matter such as dust and dirt adhering to the protective glass 37 of the optical unit 27 by the wiping member 58, A / D (Analog / Digital) The converter 44 and the LD driver 45 are connected by a bus. The CPU 40 is also connected to a hard disk 46 for storing various program codes (control programs) and an EEPROM (Electrically Erasable Programmable Read Only Memory) 47 functioning as a waveform storage unit. Here, the CPU 40, the ROM 41, and the RAM 42 constitute a microcomputer as a computer. In such a microcomputer, a storage medium 49 storing various program codes (control programs), that is, a floppy disk, a hard disk, an optical disk (CD-ROM, CD-R, CD-R / W, DVD-ROM, Connected to a program reading device 48 such as a floppy disk drive device, a CD-ROM drive device, or an MO drive device, which is a device for reading a program code stored in a DVD-RAM, a magneto-optical disk (MO), a memory card, etc. Has been.
[0058]
As a circuit for calculating the output from the light receiving element 39, an analog processing circuit 50 is connected to the output terminal of the light receiving element 39 as shown in the figure. The reflected light incident on the light receiving element 39 is converted into analog image data having a voltage value corresponding to the intensity of the light in the light receiving element 39 and output as an analog signal. The analog signal is processed by the analog processing circuit 50, converted to a digital signal by an A / D (Analog / Digital) converter 44, and passed to the CPU 40. Thereafter, the CPU 40 calculates the two-dimensional coordinates of the instruction means P.
[0059]
Various program codes (control program) stored in the hard disk 46 or various program codes (control program) stored in the storage medium 49 are written in the RAM 42 in response to the power supply to the controller 10 and various programs are stored. The code (control program) will be executed.
[0060]
Next, functions executed by the CPU 40 based on the control program will be described. First, the coordinate detection process for realizing the function of the coordinate detection means, which is one of the functions exhibited by the coordinate input / detection device 3, will be specifically described below.
[0061]
Here, FIG. 10 is a front view showing an example in which one point in the coordinate input / detection area 3a of the coordinate input / detection device 3 is indicated by the instruction means P. FIG. As shown in FIG. 10, for example, L irradiated from the left optical unit 27L.₁, L₂, L_Three, ..., L_nThe n-th probe light L among the fan-shaped lights composed of such probe lights_nIs blocked by the indicating means P, the probe light L_nDoes not reach the retroreflective member R.
[0062]
At this time, the light intensity distribution on the light receiving element 39 is considered. Here, FIG. 11 is an explanatory view schematically showing a detection operation of the light receiving element 39. If the instruction means P is not inserted in the coordinate input / detection area 3a, the light intensity distribution on the light receiving element 39 is substantially constant. However, as shown in FIG. Inserted into the probe light L_nIs blocked by the indicating means P, the probe light L_nIs not received by the light receiving element 39 of the optical unit 27, the probe light L_nThe predetermined position X on the light receiving element 39 of the optical unit 27 corresponding to_nBecomes a low light intensity region (dark spot). Position X which is a low light intensity region (dark spot)_nAppears as a peak point in the waveform of light intensity output from the light receiving element 39, the CPU 40 recognizes the appearance of such a peak point in the waveform of light intensity by a change in voltage, and this light intensity. The position X of the dark spot that became the peak point of the waveform_nIs detected.
[0063]
Also, the dark spot position X that is the peak point of the light intensity waveform_nIs detected, the dark spot position X_nThe distance from the center pixel of the light receiving element 39 to the center pixel of the light receiving element 39 is detected based on, for example, the pixel number of the light receiving element 39 (for example, pixel number m in FIG. 11). The center pixel of the light receiving element 39 is detected based on the pixel number assigned to the pixel of the light receiving element 39 corresponding to the black mark M.
[0064]
Position X, which is a low light intensity area (dark spot)_n(X on the light receiving element 39 of the left optical unit 27L_nL, X on the light receiving element 39 of the right optical unit 27R_nR) is the intercepted probe light exit / incident angle θ._nAnd X_nBy detecting_nCan know. That is, the dark spot position X_nIs the distance from the center pixel of the light receiving element 39 to a, θ_nIs a function of a
θ_n= Tan^-1(a / f) ……………………………… (1)
It can be expressed as. Here, f is the focal length of the reading lens 38. Here, θ in the left optical unit 27L_nΘ_nL, a to X_nReplace with L.
[0065]
Further, in FIG. 10, the angle θL formed by the indicating means P and the left optical unit 27L is expressed by (1) by the conversion coefficient g of the geometric relative positional relationship between the left optical unit 27L and the coordinate input / detection region 3a. X calculated by formula_nAs a function of L,
θL = g (θ_nL) ……………………………… (2)
Where θ_nL = tan^-1(X_nL / f)
It can be expressed as.
[0066]
Similarly, for the right optical unit 27R, the symbol L in the above equations (1) and (2) is replaced with the symbol R, and the geometric relative positional relationship between the right optical unit 27R and the coordinate input / detection region 3a. By the conversion coefficient h of
θR = h (θ_nR) ……………………………… (3)
Where θ_nR = tan^-1(X_nR / f)
It can be expressed as.
[0067]
Here, if the distance between the center position of the light receiving element 39 of the left optical unit 27L and the center position of the light receiving element 39 of the right optical unit 27R is w shown in FIG. 10, the instruction means P in the coordinate input / detection area 3a The two-dimensional coordinates (x, y) of the indicated point are based on the principle of triangulation.
x = w · tanθR / (tanθL + tanθR) (4)
y = w · tanθL · tanθR / (tanθL + tanθR) (5)
Can be calculated as
[0068]
These equations (1), (2), (3), (4), and (5) are stored in advance in the hard disk 46 and the storage medium 49 as a part of the control program, and (1), (2), (3), and (4). According to the equation (5), the position coordinates (x, y) of the pointing means P is X_nL, X_nCalculated as a function of R. That is, by detecting the position of the dark spot on the light receiving element 39 of the left optical unit 27L and the position of the dark spot on the light receiving element 39 of the right optical unit 27R, the position coordinates (x, y) of the pointing means P can be obtained. Will be calculated.
[0069]
Next, the characteristic process which the coordinate input / detection apparatus 3 of this Embodiment exhibits is demonstrated concretely below.
[0070]
Here, FIG. 12 is a flowchart schematically showing a flow of processing mainly including coordinate detection processing. As shown in FIG. 12, when the power of the coordinate input / detection device 3 is turned on (Y in step S1), the cover portion 52 of the unit cover mechanism 51 located at the unit closing position B is moved to the unit opening position A. A cover opening process is executed (step S2). Here, the function of the fourth cover driving means is executed. Specifically, in this cover part opening process, the cover part 52 is opened by driving the motor 54 of the unit cover mechanism 51 provided in each of the optical units 27 (the left optical unit 27L and the right optical unit 27R). The first micro switch 56 is moved in the direction of the position A until the first micro switch 56 is switched on. As described above, when the cover portion 52 of the unit cover mechanism 51 is moved to the unit opening position A, the protective glass 37 of the optical unit 27 is opened, and light projection from the protective glass 37 becomes possible.
[0071]
When the power of the coordinate input / detection device 3 is turned on (Y in step S1), driving of the light source 34 of each optical unit 27 is started, and the inside of the coordinate input / detection area 3a is driven by the driving of the light source 34. The reflected light of the fan-shaped light flux film that has traveled and is reflected from the retroreflective member R is received by the light receiving element 39 of each optical unit 27, whereby an analog processing circuit 50 and an A / D (Analog / Digital) converter 44 are received. The process waits until the peak point of the waveform of the light intensity is detected in the digital waveform signal generated via (Y in step S3).
[0072]
When the peak point of the light intensity waveform is detected (Y in step S3), the timer T starts timing (step S4), and the waveform in which the peak point of the light intensity waveform is detected is loaded into the RAM 42 (step S4). Step S5).
[0073]
In the following step S6, it is determined whether or not the waveform fetched into the RAM 42 is abnormal. The determination as to whether or not the waveform captured in the RAM 42 is abnormal is based on the case where two or more peak points (dips) of the waveform of the light intensity appear as shown in FIG. When it is wide as shown in (b), it is an abnormal waveform. Here, the function of the shape abnormality determination means is executed. 13 is a pixel of the light receiving element 39 corresponding to the detection position of the black mark M.
[0074]
If it is determined that the waveform captured in the RAM 42 is not abnormal (N in step S6), the process proceeds to step S7, where coordinate detection processing is executed. The coordinate detection process is a process of calculating the position coordinates (x, y) of the instruction means P. As described above, the position of the dark spot on the light receiving element 39 of the left optical unit 27L and the light reception of the right optical unit 27R. By detecting the position of the dark spot on the element 39, the position coordinate (x, y) is calculated.
[0075]
In the subsequent step S8, it is determined whether or not the calculated position coordinates (x, y) are continuously detected. Here, the function of the shape change determination means is executed. If the calculated position coordinates (x, y) are not continuously detected (N in step S8), the calculated position coordinates (x, y) are input to the computer 5 as input coordinates by the operation of the instruction means P. (Step S9) and reset the time count by the timer T (step S10).
[0076]
On the other hand, when the calculated position coordinates (x, y) are continuously detected (Y in step S8), the time measured by the timer T has passed a preset specified time in step S11. It is determined whether or not. If the specified time has not elapsed (N in step S11), the process proceeds to step S9 as in the case where the calculated position coordinates (x, y) are not continuously detected (N in step S8). When the time has elapsed (Y in step S11), the time counting by the timer T is reset (step S12), and the cover portion 52 of the unit cover mechanism 51 located in the unit opening position A is temporarily moved to the unit closing position. The cover part reciprocating drive process for moving to the unit opening position A after moving to B is executed (step S13). Here, the function of the second cover driving means is executed. More specifically, the cover unit reciprocating driving process is performed at the unit opening position A by driving the motor 54 of the unit cover mechanism 51 provided in each of the optical units 27 (the left optical unit 27L and the right optical unit 27R). After moving the cover 52 in the direction of the unit closing position B until the second micro switch 57 is switched on, the first micro switch 56 is further switched in the direction of the unit opening position A. It is moved until it is turned on. As described above, the movement of the cover 52 between the unit open position A and the unit close position B means that the same position coordinates (x, y) are continuously detected over a specified time. Assuming that foreign matter such as dust or dirt adheres to the protective glass 37 of the optical unit 27, the foreign matter Z is wiped off by the wiping member 58 by reciprocating the cover 52 as shown in FIG. This is because the foreign matter Z is removed from the protective glass 37.
[0077]
Similarly, when it is determined that the waveform captured in the RAM 42 is abnormal (Y in step S6), the process proceeds to step S13, and the cover portion reciprocating drive process is executed. Here, the function of the first cover driving means is executed. This is the case even when two or more peak points (dips) of the waveform of the light intensity appear as shown in FIG. 13A or when the peak point is wide as shown in FIG. This is because it is considered that foreign matter such as dust or dirt has adhered to the protective glass 37 of the unit 27, and the foreign matter is wiped and removed by the wiping member 58 by reciprocating the cover 52.
[0078]
The processes in steps S6 to S13 are repeated until the power of the coordinate input / detection device 3 is turned off (Y in step S14). Note that when the power of the coordinate input / detection device 3 is turned off (Y in step S14), the cover portion closing that moves the cover portion 52 of the unit cover mechanism 51 located in the unit opening position A to the unit closing position B is closed. Processing is executed (step S15). Here, the function of the third cover driving means is executed. Specifically, the cover portion closing process is performed by driving the motor 54 of the unit cover mechanism 51 provided in each of the optical units 27 (the left optical unit 27L and the right optical unit 27R) to close the cover portion 52. The second micro switch 57 is moved in the direction of the position B until the second micro switch 57 is switched on. Since the cover 52 of the unit cover mechanism 51 is moved to the unit closing position B in this way, the protective glass 37 of the optical unit 27 is at least covered by the cover 52, so that the coordinate input / detection device 3 is not used. In addition, it is possible to prevent foreign matters such as dust and dirt from adhering to the protective glass 37.
[0079]
In addition, in the detection standby state of the peak point of the light intensity waveform (N in step S3), before the power of the coordinate input / detection device 3 is turned off (N in step S14), as cover drive declaration means Also when the functioning wiping switch 59 is turned on (Y in step S16), the process proceeds to step S13, and the cover portion reciprocating drive process is executed. Here, the function of the fifth cover driving means is executed. Thereby, it becomes possible to remove the foreign matter such as dust and dirt adhering to the protective glass 37 of the optical unit 27 with the wiping member 58 by reciprocatingly driving the cover portion 52 with the intention of the operator. Yes.
[0080]
In the present embodiment, the protective glass 37 that is a transparent protective member is provided in the opening 28a. However, the protective glass 37 may not be provided in the opening 28a, and only the opening 28a may be provided. In this case, it is not necessary to provide the wiping member 58 below the cover portion 52. Therefore, when the protective glass 37 is not provided in the opening 28a as described above, only the function of the third cover driving unit and the function of the fourth cover driving unit are executed.
[0081]
A second embodiment of the present invention will be described with reference to FIGS. The same parts as those described in the first embodiment of the present invention are denoted by the same reference numerals, and description thereof is also omitted. This embodiment is different in the method of the coordinate input / detection device. Specifically, the coordinate input / detection device 3 used in the first embodiment of the present invention is a light shielding type, but the coordinate input / detection device 60 of the present embodiment is a light reflection type. Is.
[0082]
Here, FIG. 15 is a perspective view showing the instruction means Q used in the coordinate input / detection device 60. FIG. 16 is a front view showing an example in which one point in the coordinate input / detection area 60a of the coordinate input / detection device 60 is indicated by the instruction means Q. As shown in FIG. 15, the tip portion Q of the pointing means Q used for pointing to one point in the coordinate input / detection area 60a of the coordinate input / detection device 60.₁Is provided with a retroreflective member 61. The retroreflective member 61 is formed by arranging a large number of conical corner cubes, for example, and has a characteristic of reflecting incident light toward a predetermined position regardless of the incident angle. For example, the probe light L projected from the left optical unit 27L_nAs shown in FIG. 16, the retroreflected light L reflected by the retroreflective member 61 and follows the same optical path again._nThe light is received by the optical unit 27 as'. Therefore, as shown in FIG. 16, in the coordinate input / detection device 60 of the present embodiment, the coordinate input / detection region 3a is the same as the coordinate input / detection device 3 used in the first embodiment of the present invention. It is not necessary to provide the retroreflective member R in the peripheral part except for the lower part of. However, in the coordinate input / detection device 60 of the present embodiment, instead of the black mark M (M1, M2, M3, M4) of the coordinate input / detection device 3, the retroreflective member N (N1, N2, N3, N4). In the coordinate input / detection region 60a, a shielding plate 62 is provided that shields the retroreflective member N1 from the left optical unit 27L and shields the retroreflective member N2 from the right optical unit 27R.
[0083]
Accordingly, the tip end portion Q provided with the retroreflective member 61 of such an indicating means Q.₁Is inserted into an appropriate position (x, y) of the coordinate input / detection region 60a of the coordinate input / detection device 60, and the probe light L in the fan-shaped light flux film projected from the optical unit 27, for example._nIs the tip Q of the indicating means Q₁Is reflected by the retroreflected light L_n′ Is received by the light receiving element 39 of the optical unit 27. In this way, the light receiving element 39 is retroreflected light L._nWhen ′ is received, the retroreflected light L_nA predetermined position X on the light receiving element 39 of the optical unit 27 corresponding to '_nL is a region having a high light intensity (bright point). More specifically, the probe light L in the light flux film_nIs the tip Q of the indicating means Q₁The peak point appears in the light intensity waveform output from the light receiving element 39 as shown in FIG.
[0084]
Accordingly, even when such a light reflection type coordinate input / detection device 60 is applied to the electronic blackboard system 1, a peak point appears in the light intensity waveform. As in the case of using the apparatus 3, the coordinate detection process shown in step S7 in FIG. 12 can be executed based on the peak point appearing in the light intensity waveform.
[0085]
And according to the coordinate input / detection device 60 of the present embodiment, since the same optical unit 27 as the coordinate input / detection device 3 used in the first embodiment is used, Similar effects can be achieved.
[0086]
A third embodiment of the present invention will be described with reference to FIG. In addition, the same code | symbol is used about the same part as the part demonstrated in 1st embodiment of this invention, or 2nd embodiment of this invention, and description is also abbreviate | omitted. This embodiment is a modification of the optical unit. Specifically, in the optical unit 27 (left optical unit 27L, right optical unit 27R) used in the first embodiment or the second embodiment of the present invention, a fan-shaped light flux film is projected. Thus, the coordinate input / detection area is formed. However, the optical unit of the present embodiment has a rotary scanning system such as a polygon mirror, and the light beam emitted from the light source by the rotary scanning system is radiated. The coordinate input / detection area is formed by projecting light.
[0087]
Here, FIG. 18 is a plan view schematically showing the optical unit 70. As shown in FIG. 18, the optical unit 70 (here, only the left optical unit 70L is shown) has a drive circuit (not shown) inside a housing 77 having an opening 77a communicating with the outside. And a light projecting means 70a composed of an LD (Laser Diode: semiconductor laser) 71, a half mirror 72, a polygon mirror 73, and a condenser lens 74, and a light receiving element 75. Yes. The opening 77a is provided with a protective glass 78 which is a transparent protective member.
[0088]
The light receiving element 75 is composed of a CCD provided at a distance f from the condenser lens 74 (f is the focal length of the condenser lens 74). In such an optical unit 70, the laser light emitted from the LD 71 is transmitted through the half mirror 72, and then sequentially reflected radially by the polygon mirror 73 that is rotationally driven by a pulse motor (not shown). Therefore, the optical unit 70 repeatedly projects the beam light radially. That is, the coordinate input / detection region 76 is formed by the light beams projected radially from the two optical units 70.
[0089]
Even when such an optical unit 70 is applied to the coordinate input / detection devices 3 and 60 in place of the optical unit 27 (the left optical unit 27L and the right optical unit 27R), the light is blocked or reflected by the instruction means. A peak point appears in the waveform of the light intensity output from the light receiving element 75. Therefore, since it is known in the art, a detailed description is omitted, but the number of pulses of the pulse motor that rotates the polygon mirror 73 is detected based on the peak point of the light intensity waveform output from the light receiving element 75. Then, the output angle of the light shielded or reflected by the instruction means is determined for each optical unit 70 according to the detected number of pulses, and the position coordinates where the instruction means is inserted by the triangulation method based on those emission angles are obtained. Can be detected.
[0090]
Even when such an optical unit 70 is applied to the coordinate input / detection devices 3 and 60 in place of the optical unit 27 (the left optical unit 27L and the right optical unit 27R), the light receiving element of the optical unit 70 is used. Since the protective glass 78 which is a transparent protective member is provided in the opening 77a of the housing 77 including 75, the unit cover mechanism 51 functioning as the cover means described in the first embodiment is used as the optical unit 70. By providing them at a predetermined timing, it is possible to achieve the same operational effects as the first embodiment.
[0091]
In each embodiment, the electronic blackboard system 1 includes the coordinate input / detection devices 3, 60, and 70 in a plasma display panel (PDP) 2 that is a display device. However, the present invention is not limited to this. Alternatively, an LCD (Liquid Crystal Display), a liquid crystal rear projection display, or the like may be applied as the display device. Furthermore, not only the display device but also the coordinate input / detection devices 3, 60, 70 may be provided in a whiteboard that functions as a writing board.
[0092]
In each embodiment, the controller 10 is provided separately from the computer 5. However, the present invention is not limited to this. The controller 10 is incorporated in the computer 5 so that the computer 5 functions as the controller 10. Also good.
[0093]
In each embodiment, the coordinate input / detection device is integrated into the electronic blackboard system. However, the present invention is not limited to this, and the coordinate input / detection device is detachable from the display device or the writing board. It is good also as a structure.
[0094]
Further, in each embodiment, a floppy disk, hard disk, optical disk (CD-ROM, CD-R, CD-R / W, DVD) is used as the storage medium 26 or storage medium 49 storing various program codes (control programs). -ROM, DVD-RAM, etc.), magneto-optical disk (MO), memory card, etc. are applied. However, the present invention is not limited to this, and the storage medium is not limited to a medium independent of a computer, but may be a LAN or the Internet. A storage medium that downloads and stores or temporarily stores the transmitted program is also included.
[0095]
【The invention's effect】
  BookAccording to the coordinate input / detection device of the invention, the optical unit having the light receiving element provided in the vicinity of the opening communicating with the outside has coordinates based on the intensity distribution of the light received by the light receiving element through the opening. In a coordinate input / detection device for detecting a two-dimensional position coordinate of a pointing member such as a pointing member or a finger that points in the input / detection area, a cover means that can freely move to a position for closing and opening the opening of the optical unit. For example, when the apparatus is not used, the opening can be closed by the cover means, so that foreign matter such as dust and dirt can be prevented from entering the optical unit, and position coordinate detection can be performed. Reliability can be improved.
[0096]
  BookAccording to the coordinate input / detection device of the invention, the light receiving element is provided in the vicinity of the opening communicating with the outside, and the transparent protective member is provided in the opening, and the light receiving element is disposed through the opening. In a coordinate input / detection device for detecting a two-dimensional position coordinate of a pointing means such as a pointing member or a finger that points within a coordinate input / detection region based on the intensity distribution of received light, the opening of the optical unit is closed And a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening. Since the cover means can be advanced and retracted to a position where the opening is closed and opened at a predetermined timing, foreign matter such as dust and dirt on the transparent protective member is removed along with the movement of the cover means. It can be wiped by the member, thereby improving the reliability of the position coordinate detection.
[0097]
  BookAccording to the invention,SaidIn the coordinate input / detection device, the shape abnormality determining means for determining whether or not the shape of the intensity distribution of the light received by the light receiving element is abnormal, and the shape of the light intensity distribution is abnormal by the shape abnormality determining means. And a first cover driving means for closing and opening the opening by moving the cover means forward and backward when it is determined that, for example, the peak point (dip) of the shape of the light intensity distribution is 2 If it appears more than one place or if it is wide, it is assumed that the shape of the light intensity distribution is abnormal due to the presence of foreign matter such as dust on the transparent protective member, and the opening is closed. Since the cover means can be advanced and retracted to the open position, foreign matter such as dust and dirt on the transparent protective member can be wiped by the wiping member as the cover means moves, and the reliability of position coordinate detection is improved. Improvement Rukoto can.
[0098]
  BookAccording to the invention,SaidIn the coordinate input / detection device, the shape change determination means for determining whether or not the temporal change in the shape of the intensity distribution of the light received by the light receiving element is abnormal, and the light intensity distribution by the shape change determination means The second cover driving means for moving the cover means forward and backward to close and open the opening when it is determined that the temporal change in the shape of the light is abnormal, for example, the shape of the light intensity distribution When the peak points (dips) appear at the same location for a predetermined time or longer, foreign matter such as dust or dirt exists on the transparent protective member, so the temporal change in the shape of the light intensity distribution is abnormal. Since the cover means can be advanced and retracted to the position where the opening is closed and opened, the foreign material such as dust and dirt on the transparent protective member is wiped by the wiping member in accordance with the movement of the cover means. In , It is possible to improve the reliability of the position coordinate detection.
[0099]
  BookAccording to the invention,SaidIn the coordinate input / detection device, the third cover driving means for driving the cover means so as to close the opening when the operation of the apparatus is finished is provided. It is possible to reliably prevent foreign matters from entering the optical unit and foreign matters such as dust and dirt from adhering to the transparent protective member.
[0100]
  BookAccording to the invention,SaidIn the coordinate input / detection device of the present invention, when the device is started, the opening portion is closed while the device is not used by providing the fourth cover driving means for driving the cover means so as to open the opening. However, since the opening can be opened when the apparatus is activated, the two-dimensional position coordinates of the pointing means can be reliably detected.
[0101]
  BookAccording to the invention,SaidIn the coordinate input / detection device, a cover drive declaring means for declaring the drive of the cover means, and when the cover means is declared to be driven by the cover drive declaring means, the cover means is advanced and retracted to open the opening. By providing the fifth cover driving means for closing and opening the part, the cover means can be advanced and retracted to the position for closing and opening the opening by the operator's intention. Foreign matter such as dust can be wiped off by the wiping member with the movement of the cover means, and the reliability of position coordinate detection can be improved.
[0102]
  BookAccording to the electronic blackboard system of the invention, a display device for displaying characters and images, and the coordinate input / detection area are arranged on the display surface of the display device so as to coincide with each other. A coordinate input / detection device according to claim 1 and a control device that performs display control of the display device based on an input from the coordinate input / detection device, wherein the display device and the coordinate input / detection device are used. By configuring the display surface and writing surface of the electronic blackboard part, it does not have a physical surface such as a coordinate input surface (touch panel surface), and even when it is used by being mounted on the display surface of a display device It is possible to provide an electronic blackboard system that is excellent in visibility and has the same effect as the coordinate input / detection device according to any one of claims 1 to 7 at a low cost.
[0103]
  BookAccording to the electronic blackboard system of the invention, the writing board that accepts writing of characters and images, and the coordinate input / detection area are arranged on the writing surface of the writing board so as to coincide with each other. A coordinate input / detection device, and a control device that controls information written on the writing board based on an input from the coordinate input / detection device, the writing board and the coordinate input / detection device Even if the writing surface of the electronic blackboard part is used to configure the writing surface of the writing board without using a physical surface such as a coordinate input surface (touch panel surface) An electronic blackboard system that has excellent visibility and exhibits the same effect as the coordinate input / detection device according to any one of claims 1 to 7 is inexpensive. It is possible to provide.
[0104]
  BookAccording to the storage medium of the invention, an optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, and the position of the optical unit is closed and opened. Used in a coordinate input / detection device comprising: a flexible cover means; and a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening. Reading to a computer that causes the computer to detect the two-dimensional position coordinates of the pointing means such as a pointing member or a finger that points within the coordinate input / detection area based on the intensity distribution of the light received by the light receiving element through the opening A storage medium storing a possible program, wherein the program determines whether or not the shape of the intensity distribution of light received by the light receiving element is abnormal Causing the computer to execute a shape abnormality determining function and a first cover driving function for moving the cover means forward and backward to close and open the opening when it is determined that the shape of the light intensity distribution is abnormal Thus, for example, when two or more peak points (dips) in the shape of the light intensity distribution appear or are wide, there is a foreign matter such as dust or dust on the transparent protective member. As the shape of the intensity distribution of the cover is abnormal, the cover means can be moved back and forth to the position where the opening is closed and opened, so that foreign matter such as dust and dirt on the transparent protective member can be moved by the movement of the cover means. Along with this, the wiping member can wipe off, and the reliability of position coordinate detection can be improved.
[0105]
  BookAccording to the storage medium of the invention, an optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, and the position of the optical unit is closed and opened. Used in a coordinate input / detection device comprising: a flexible cover means; and a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening. Reading to a computer that causes the computer to detect the two-dimensional position coordinates of the pointing means such as a pointing member or a finger that points within the coordinate input / detection area based on the intensity distribution of the light received by the light receiving element through the opening A storage medium storing a possible program, wherein the program is abnormal in temporal change in the shape of the intensity distribution of light received by the light receiving element. And a second cover driving function for closing and opening the opening by moving the cover means forward and backward when it is determined that the temporal change in the shape of the light intensity distribution is abnormal. When the peak point (dip) of the shape of the light intensity distribution has appeared at the same location for a predetermined time or longer, for example, a foreign substance such as dust or dust on the transparent protective member. Since the temporal change in the shape of the light intensity distribution is abnormal due to the presence of the cover means, the cover means can be advanced and retracted to the position where the opening is closed and opened. Foreign matter such as dust can be wiped off by the wiping member with the movement of the cover means, and the reliability of position coordinate detection can be improved.
[0106]
  BookAccording to the storage medium of the invention, the coordinate input includes: an optical unit having a light receiving element provided in the vicinity of an opening communicating with the outside; and a cover means that can be moved back and forth to close and open the opening of the optical unit. / Detection of two-dimensional position coordinates of pointing means such as a pointing member or a finger that indicates the inside of a coordinate input / detection area based on the intensity distribution of light received by the light receiving element through the opening. A computer-readable storage medium storing a computer-readable program, wherein the program drives the cover means to close the opening when the operation of the apparatus ends. By causing the computer to execute the drive function, foreign matter such as dust and dirt can enter the optical unit and the foreign matter such as dust and dirt can be transparent when the device is not used. Adhesion to protection member on can be reliably prevented.
[0107]
  BookAccording to the storage medium of the invention, the coordinate input includes: an optical unit having a light receiving element provided in the vicinity of an opening communicating with the outside; and a cover means that can be moved back and forth to close and open the opening of the optical unit. / Detection of two-dimensional position coordinates of pointing means such as a pointing member or a finger that indicates the inside of a coordinate input / detection area based on the intensity distribution of light received by the light receiving element through the opening. A computer-readable storage medium storing a computer-readable program, wherein the program drives the cover means so as to open the opening when the apparatus is activated. By causing the computer to execute the function, the opening can be opened when the apparatus is activated even if the opening is closed while the apparatus is not used. , It is possible to reliably detect the two-dimensional position coordinates of the pointing means.
[0108]
  BookThe storage medium of the invention is provided with an optical unit provided with a light receiving element in the vicinity of an opening communicating with the outside and a transparent protective member provided in the opening, and can be moved forward and backward to a position for closing and opening the opening of the optical unit. A cover means, and a wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening. The computer can cause the computer to detect the two-dimensional position coordinates of the pointing means such as the pointing member or the finger indicating the inside of the coordinate input / detection area based on the intensity distribution of the light received by the light receiving element via A storage medium storing a program, wherein the program includes a cover drive declaration function for declaring drive of the cover means, and the cover means By causing the computer to execute a fifth cover drive function for closing and opening the opening by advancing and retracting the cover means when driving is declared, the opening is closed and opened by the operator's intention. Since the cover means can be moved back and forth to the position where the cover means moves, foreign matter such as dust and dirt on the transparent protective member can be wiped by the wiping member along with the movement of the cover means, improving the reliability of position coordinate detection be able to.
[Brief description of the drawings]
FIG. 1 is an external perspective view schematically showing an electronic blackboard system according to a first embodiment of the present invention.
FIG. 2 is a block diagram showing an electrical connection of each part built in the electronic blackboard system.
FIG. 3 is a block diagram showing electrical connection of each unit built in the computer.
FIG. 4 is an explanatory diagram schematically showing a configuration of a coordinate input / detection device.
FIG. 5 is a longitudinal sectional front view showing the internal structure of the optical unit.
FIG. 6 is a bottom view thereof.
7A is a plan view showing a state in which the cover portion is in the unit open position, and FIG. 7B is a plan view showing a state in which the cover portion has been moved to the unit closed position.
8A and 8B show a cover portion, where FIG. 8A is a front view and FIG. 8B is a side view.
FIG. 9 is a block diagram showing electrical connection of each part of the coordinate input / detection device.
FIG. 10 is a front view showing an example in which one point in a coordinate input / detection area of the coordinate input / detection device is pointed by an instruction unit;
FIG. 11 is an explanatory diagram schematically showing a detection operation of a light receiving element.
FIG. 12 is a flowchart schematically showing a flow of processing mainly including coordinate detection processing.
FIG. 13 shows an example of a light intensity waveform, where (a) is a waveform diagram showing a case where two or more peak points (dips) of the light intensity waveform appear, and (b) is a waveform of the light intensity waveform. It is a wave form diagram which shows the case where a peak point (dip) is wide.
FIG. 14 is an explanatory view showing a state in which foreign matter is removed from the protective glass by a wiping member.
FIG. 15 is a perspective view showing an instruction unit used in the coordinate input / detection apparatus according to the second embodiment of the present invention.
FIG. 16 is a front view showing an example in which one point in a coordinate input / detection area of the coordinate input / detection device is pointed by an instruction unit;
FIG. 17 is a graph showing an example of a waveform of light intensity output from a CCD.
FIG. 18 is a plan view schematically showing an optical unit according to the third embodiment of the present invention.
[Explanation of symbols]
1 Electronic blackboard system
2 display devices
2a Display surface
3,60 Coordinate input / detection device
3a, 60a, 76 Coordinate input / detection area
4 electronic blackboard
5 Control device
26, 49 storage media
27,70 Optical unit
28a, 77a opening
37, 78 Transparent protective member
39,75 light receiving element
52 Cover means
58 Wiping member
59 Cover drive declaration means
P, Q instruction means

Claims (7)

A light receiving element is provided in the vicinity of the opening communicating with the outside and a transparent protective member is provided in the opening, and coordinates are input based on the intensity distribution of light received by the light receiving element through the opening. In the coordinate input / detection device for detecting the two-dimensional position coordinates of the pointing means such as the pointing member and the finger that pointed within the detection area, the cover means that can be moved back and forth to the position for closing and opening the opening of the optical unit; The wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening, and whether the shape of the intensity distribution of the light received by the light receiving element is abnormal. A shape abnormality judging means for judging whether or not, and when the shape abnormality judging means judges that the shape of the light intensity distribution is abnormal, the cover means is advanced and retracted to close and close the opening. Coordinate input / detection device, characterized in that it comprises a first cover driving means for opening, the. A light receiving element is provided in the vicinity of the opening communicating with the outside and a transparent protective member is provided in the opening, and coordinates are input based on the intensity distribution of light received by the light receiving element through the opening. In the coordinate input / detection device for detecting the two-dimensional position coordinates of the pointing means such as the pointing member and the finger that pointed within the detection area, the cover means that can be moved back and forth to the position for closing and opening the opening of the optical unit; A wiping member provided on the cover means for wiping the transparent protective member when the cover means closes and opens the opening, and a temporal change in the shape of the intensity distribution of the light received by the light receiving element. A shape change judging means for judging whether or not it is abnormal, and when the shape change judging means judges that the temporal change in the shape of the light intensity distribution is abnormal, the cover means is moved forward and backward. Allowed by the coordinate input / detection device, characterized in that it comprises a second cover driving means for closing and opening, the said opening. 3. The coordinate input / detection device according to claim 1, further comprising third cover driving means for driving the cover means so as to close the opening when the operation of the apparatus is finished . 4. The coordinate input / detection device according to claim 3, further comprising fourth cover driving means for driving the cover means so as to open the opening when the apparatus is activated . Cover drive declaring means for declaring the drive of the cover means, and a fifth means for closing and opening the opening by advancing and retracting the cover means when the drive of the cover means is declared by the cover drive declaring means. The coordinate input / detection device according to claim 1, further comprising a cover driving unit . An optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, cover means that can be moved back and forth to close and open the opening of the optical unit, and the cover And a wiping member for wiping the transparent protective member when the cover means closes and opens the opening, and is used for a coordinate input / detection device, and the light receiving element through the opening. Stores a computer-readable program that causes the computer to detect the two-dimensional position coordinates of the pointing means such as the pointing member and the finger that pointed within the coordinate input / detection area based on the intensity distribution of the light received by the A storage medium, wherein the program includes a shape abnormality determination function for determining whether or not the shape of the intensity distribution of light received by the light receiving element is abnormal, and a light Storage medium to execute a first cover driving function of closing and opening said opening by reciprocating said cover means when the shape of the intensity distribution is determined to be abnormal in the computer. An optical unit in which a light receiving element is provided in the vicinity of an opening communicating with the outside and a transparent protective member is provided in the opening, cover means that can be moved back and forth to close and open the opening of the optical unit, and the cover provided means and wiping member said cover means to wipe the transparent protective member upon release closing and opening the opening, used in the coordinate input / detection device including a light receiving via said opening Storing a computer-readable program that causes a computer to detect the two-dimensional position coordinates of a pointing means such as a pointing member or a finger that points within the coordinate input / detection area based on the intensity distribution of light received by the element; And a program for determining whether the temporal change in the shape of the intensity distribution of the light received by the light receiving element is abnormal. And a second cover driving function for moving the cover means forward and backward to close and open the opening when it is determined that the temporal change in the shape of the light intensity distribution is abnormal. Storage medium

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